Combi-sensor systems
Certain aspects pertain to a combination sensor comprising a set of physical sensors facing different directions proximate a structure, and configured to measure solar radiation in different directions. The combination sensor also comprises a virtual facade-aligned sensor configured to determine a combi-sensor value at a facade of the structure based on solar radiation readings from the set of physical sensors.
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This application is a national stage application under 35 U.S.C. § 371 to International PCT Application PCT/US15/52822 titled “COMBI-SENSOR SYSTEMS,” filed on Sep. 29, 2015, which claims priority to and benefit of U.S. Provisional Application No. 62/057,104, titled “COMBI-SENSOR SYSTEMS,” filed on Sep. 29, 2014, which are hereby incorporated by reference in their entirety and for all purposes.
FIELDThe present disclosure relates to multiple sensor inputs and data handling related to same, in particular combi-sensor systems and methods of determining combi-sensor values.
BACKGROUNDElectrochromism is a phenomenon in which a material exhibits a reversible electrochemically-mediated change in an optical property when placed in a different electronic state, typically by being subjected to a voltage change. The optical property is typically one or more of color, transmittance, absorbance, and reflectance. One well known electrochromic material is tungsten oxide (WO3). Tungsten oxide is a cathodic electrochromic material in which a coloration transition, transparent to blue, occurs by electrochemical reduction.
Electrochromic materials may be incorporated into, for example, windows for home, commercial and other uses. The color, transmittance, absorbance, and/or reflectance of such windows may be changed by inducing a change in the electrochromic material, that is, electrochromic windows are windows that can be darkened or lightened electronically. A small voltage applied to an electrochromic device of the window will cause them to darken; reversing the voltage causes them to lighten. This capability allows control of the amount of light that passes through the windows, and presents an opportunity for electrochromic windows to be used as energy-saving devices.
While electrochromism was discovered in the 1960s, electrochromic devices, and particularly electrochromic windows, still unfortunately suffer various problems and have not begun to realize their full commercial potential despite many recent advances in electrochromic technology, apparatus and related methods of making and/or using electrochromic devices.
SUMMARYIn certain aspects, a combi-sensor system may be used to improve control of building systems in a structure having fewer physical sensors than azimuthal facade positions. For example, a combi-sensor system may determine a combi-sensor value for a virtual sensor facing outward from a facade (or facet thereof) lacking its own physical sensor. The combi-sensor system can determine this combi-sensor value for this virtual sensor based on readings taken by two or more physical sensors facing different directions installed at the building.
According to certain aspects, a combi-sensor system uses either a combination technique or an interpolation technique to determine the combi-sensor value. The first technique combines readings from two or more physical sensors to determine an aggregate value that applies to all facade orientations at that time. The readings can be combined by: 1) taking the maximum value of the physical sensor readings, 2) taking the average value of the physical sensor readings, or 3) taking a sum of the physical sensor readings. The second technique interpolates readings from two or more physical sensors to a virtual facade-aligned sensor using a vector algorithm. Combi-sensor systems may use any combination of the aforementioned three combination methods.
A combi-sensor system generally comprises two or more physical sensors facing distinctly different directions (e.g., having azimuthal angles that vary by more than about 80 degrees, by more than about 70 degrees, by more than about 60 degrees, by more than about 50 degrees, etc.). For example, a combi-sensor system may include three physical sensors facing distinctly different directions. As another example, a combi-sensor system may include four physical sensors facing distinctly different directions. Since these physical sensors face different directions, they measure solar irradiance values from these distinctly different directions. The solar radiation values are typically recorded over time, for example, on a periodic basis over a day. The solar radiation profiles of the physical sensor values recorded over time sometimes have a shape similar to bell-shaped Gaussian-type curves. When solar radiation profiles from physical sensors facing distinctly different azimuthal angles are overlaid, the curves are somewhat similar in shape to each other and/or shifted time-wise from each other. The maximums, averages or sums of the profiles may be used to determine values from facades or directions where there are no physical sensors. In this way, the complexity of having many sensors facing in many directions is avoided. Simpler physical systems are realized, i.e. less physical sensors, while retaining the input as if one had many more physical sensors.
In some examples of combi-sensor systems described herein, the physical sensors are facing directions that are approximately orthogonal to each other. For example, a combi-sensor system may comprise four physical sensors facing approximately orthogonal directions (e.g., approximately in the directions of North (N), South (S), East (E) and West (W)). In other examples, the combi-sensor system includes three physical sensors installed on a building. In some cases, a comb-sensor system comprises three physical sensors that are facing approximately orthogonal directions. In certain examples where the building is located in a northern latitude, the three orthogonally-directed physical sensors face approximately W, E, and S. In certain examples where the building is located at a southern latitude, the three orthogonally-directed physical sensors face approximately W, E, and N.
In certain embodiments, a combi-sensor value may be used as input to control a building system. For example, a combi-sensor value may be used as input to a control system that determines tinting decisions for electrochromic (EC) window(s) or in a building and controls power to the window(s) to implement the tinting decisions. An example of such a control system is described in Section X. This control system uses operations of what are described as “Modules A, B, and C” of Intelligence™ EC control software to determine the tint decisions (Intelligence™ is commercially available from View, Inc. of Milpitas, Calif.). In one embodiment, this control system uses Module A to determine a tint level that provides occupant comfort from glare to a workspace from sunlight penetrating a room and uses Module B to increase the tint level based on clear sky predictions of solar irradiance at that time of the day. Module C may then use irradiance readings taken by one or more sensors (either physical or virtual) to override the tint level from Modules A and B, or not. For example, a combi-sensor value may be used as input to Module C. Module C may override the tint level from Modules A and B to make the tint level lighter based on the combi-sensor value. That is, if the combi-sensor value is higher than the clear sky irradiance level used in Modules A and B, then Module C will not override Modules A and B and will ignore the higher combi-sensor irradiance value. If the combi-sensor value is lower than the clear sky irradiance level used in Modules A and B, then Module C will override Modules A and B. For illustration purposes, many embodiments are described herein with reference to input to the Modules of this particular control system, it would be understood however that the combi-sensor system can be used to generate combi-sensor value(s) as input for other control systems that rely on irradiance measurements as well, for example other smart window control algorithms or control algorithms for other systems such as HVAC, building management systems (BMS), solar tracking systems, etc. Embodiments disclosed are useful for determining solar irradiance on surfaces that do not have a physical sensor associated with the surface by using a “virtual sensor” which derives output from readings from physical sensors in other locations. In one embodiment a combi-sensor system includes hardware and software, while other aspects are embodied in software and/or methods alone, i.e. without physical components.
In certain embodiments, a combi-sensor system comprises a set of at least three azimuthally distinct physical sensors (i.e. directed to different azimuth angles). In some aspects, a combi-sensor system comprises four azimuthally distinct physical sensors. In some aspects, a combi-sensor system comprises three azimuthally distinct physical sensors. In some cases, these azimuthally distinct physical sensors are oriented in approximately orthogonal directions. The physical sensors are typically, though not necessarily, located on facades of a building. The combi-sensor system uses these physical sensors to determine solar irradiation for other facades not having physical sensors thereon. In one embodiment, the combi-sensor system comprises three orthogonally-directed physical sensors directed to North, 90 degrees from North and 270 degrees from North. In one embodiment, the combi-sensor system comprises three orthogonally-directed physical sensors directed to 90 degrees from North, 180 degrees from North, and 270 degrees from North. Combi-sensor systems may include more sensors, e.g. between two and twenty sensors, or between two and fifteen sensors, or between two and ten sensors, or between two and five sensors, depending on for example, how many facets and/or levels a structure has, the level of granularity and precision one requires the output to be, and the like.
Certain aspects pertain to a combination sensor comprising a set of physical sensors facing different directions proximate a structure (e.g., a building). The physical sensors are configured to measure solar radiation in different directions. The combination sensor further comprising a virtual facade-aligned sensor configured to determine a combi-sensor value at a facade of the structure based on solar radiation readings from the set of physical sensors.
Certain aspects pertain to methods comprising determining solar radiation readings taken by a set of physical sensors and determining a combi-sensor value of a virtual facade-aligned sensor based on the solar radiation readings taken by the set of physical sensors. In some cases, the set of physical sensors are facing different directions proximate a structure (e.g., a building) and are configured to measure solar radiation in different directions.
These and other features and embodiments will be described in more detail below with reference to the drawings.
I. Introduction
Buildings and other structures sometimes have sensors installed to measure solar radiation such as photosensors, photometers, radiometers, ultraviolet sensors and the like. The measurements taken by these sensors can be used as input to control building systems (e.g., HVAC, electrochromic window systems, for example, to maintain a comfortable environment for its occupants or maximize power generation, and solar tracking, for example, to maintain a comfortable environment for its occupants or maximize power generation, etc. For structures having smart windows that tint on demand, for example, ideally, a structure would have a separate sensor installed on each wall at each floor (i.e. there is at least one sensor facing the direction of every facet of the structure). The number and locations of sensors installed on a structure, however, are usually limited. For example, the number and location of sensors visible from outside the building may be restricted for aesthetic reasons. Also, it may not be practical to have a sensor on every facet of a multi-faceted structure. Moreover, sensors installed on a structure can be become inoperable or malfunction making sensor data unavailable. Also, a sensor could become misaligned from the planned direction. Using data from a sensor that is substantially misaligned from the facet direction could result in improper or fluctuating control of the building systems that may be noticeable and/or uncomfortable to occupants of the building. For these reasons, sensor data is generally not available for every facet of the structure.
As mentioned above, physical sensors can be misaligned from the direction to which they are intended to be configured (e.g., installed) to measure solar radiation. This misalignment can result in the sensors taking solar radiation measurements (also called “lux” in some instances herein) that do not correspond to the amount of solar radiation that impinges the façade from that direction. The measurements correspond to the misaligned direction. This misalignment can result in the sensor providing inaccurate data as input to the control system such as a window controller electronically tinting windows or shading systems on that façade. Combi-sensor systems can account for misalignment and provide accurate sensor data, as well as allow for less physical sensors in a given installation while retaining a data input approximating that which would be available with more physical sensors.
II. Introduction to Combi-Sensor Systems
In certain aspects, a combi-sensor system may be used to improve control of building systems in a structure having fewer physical sensors than azimuthal facade positions and/or fewer physical sensors than vertical floors in the building. For example, a combi-sensor system may determine a combi-sensor value for a “virtual” sensor facing outward from a facade (or facet thereof) lacking its own physical sensor. The combi-sensor system can determine this combi-sensor value for this virtual sensor based on readings taken by two or more physical sensors facing different directions installed at the building.
According to certain aspects, a combi-sensor system uses either a combination technique or an interpolation technique to determine the combi-sensor value. The first technique combines readings from two or more physical sensors to determine an aggregate value that applies to all facade orientations at that time. The readings can be combined by: 1) taking the maximum value of the physical sensor readings, 2) taking the average value of the physical sensor readings, or 3) taking a sum of the physical sensor readings. The second technique interpolates readings from two or more physical sensors to a virtual facade-aligned sensor using a vector algorithm.
A combi-sensor system generally comprises two or more physical sensors in different locations, azimuthally (as observed in a plane parallel to the floors of a building or, for example, located at different vertical locations, e.g. floors, of a building). For azimuthally distinct physical sensors, for example, physical sensors facing distinctly different directions (e.g., having azimuthal angles that vary by more than about 80 degrees, by more than about 70 degrees, by more than about 60 degrees, by more than about 50 degrees, etc.). For example, a combi-sensor system may include three physical sensors facing distinctly different directions. As another example, a combi-sensor system may include four physical sensors facing distinctly different directions. Since these physical sensors face different directions, they measure solar irradiance values from these distinctly different directions. The solar radiation values are typically recorded over time, for example, on a periodic basis over a day. The solar radiation profiles of the physical sensor values recorded over time sometimes have a shape similar to bell-shaped Gaussian-type curves. When solar radiation profiles from physical sensors facing distinctly different azimuthal angles are overlaid, the curves are somewhat similar in shape to each other and/or shifted time-wise from each other. For example, these curve overlays can be used to determine or estimate solar irradiance occurring on facades with azimuthal orientations different from those facades bearing physical sensors.
In some examples of combi-sensor systems described herein, the physical sensors are facing directions that are approximately orthogonal to each other. For example, a combi-sensor system may comprise four physical sensors facing approximately orthogonal directions (e.g., approximately in the directions of North (N), South (S), East (E) and West (W)). In other examples, the combi-sensor system includes three physical sensors installed on a building. In some cases, a comb-sensor system comprises three physical sensors that are facing approximately orthogonal directions. In certain examples where the building is located in a northern latitude, the three orthogonally-directed physical sensors face approximately W, E, and S. In certain examples where the building is located at a southern latitude, the three orthogonally-directed physical sensors face approximately W, E, and N.
As described herein, a physical sensor may be considered to face approximately in a particular direction if it is, for example, within 5 degrees of the direction, within 2 degrees of the direction, within 3 degrees of the direction, in a range of 1-10 degrees of the direction, in a range of 5-15 degrees of the direction, and/or in a range of 1-5 degrees of the direction.
In certain embodiments, a combi-sensor value may be used as input to control a building system. For example, a combi-sensor value may be used as input to a control system that determines tinting decisions for electrochromic (EC) window(s) or in a building and controls power to the window(s) to implement the tinting decisions. An example of such a control system is described in Section X. This control system uses operations of Modules A, B, and C to determine the tint decisions. In one embodiment, this control system uses Module A to determine a tint level that provides occupant comfort from glare to a workspace from sunlight penetrating a room and uses Module B to increase the tint level based on clear sky predictions of solar irradiance at that time of the day. Module C may then use irradiance readings taken by one or more sensors (either physical or virtual) to override the tint level from Modules A and B. For example, a combi-sensor value may be used as input to Module C. Module C may override the tint level from Modules A and B to make the tint level lighter based on the combi-sensor value. That is, if the combi-sensor value is higher than the clear sky irradiance level used in Modules A and B, then Module C will not override Modules A and B and will ignore the higher combi-sensor irradiance value. If the combi-sensor value is lower than the clear sky irradiance level used in Modules A and B, then Module C will override Modules A and B. For illustration purposes, many embodiments are described herein with reference to input to the Modules of this control system, it would be understood however that the combi-sensor system can be used to generate combi-sensor value(s) as input for other systems as well.
III. Examples of Combi-Sensor Systems
In certain embodiments, a combi-sensor system comprises a set of at least three azimuthally distinct physical sensors (i.e. directed to different azimuth angles). In some aspects, a combi-sensor system comprises four azimuthally distinct physical sensors. In some aspects, a combi-sensor system comprises three azimuthally distinct physical sensors. In some cases, these azimuthally distinct physical sensors are oriented in approximately orthogonal directions. That is, each of these orthogonally-directed sensors is directed at an azimuth angle that is approximately 90 degrees (e.g., 90 degrees±5 degrees, 90 degrees±2 degrees, 90 degrees±1 degrees) from the azimuth angle of at least one other physical sensor. In some examples of systems with four orthogonally-directed sensors, the physical sensors may directed to face approximately N, E, S, and W (e.g., ±5 degrees from North, ±5 degrees from East, ±5 degrees from South, ±5 degrees from West; ±3 degrees from N, E, S, W; and ±2 degrees from N, E, S, W; ±1 degrees from N, E, S, W). In one embodiment, the system comprises four orthogonally-directed physical sensors directed to North, 90 degrees from North, 180 degrees from North, and 270 degrees from North.
In
In
In certain aspects, the combi-sensor system 140 is in communication with one or more window controllers for controlling EC windows in the multifaceted structure.
For buildings geographically located in the Northern hemisphere, the north facing facades are only exposed to morning and evening sun for a brief time (and only in summer months) which would be covered by an east and west facing physical sensor combined. In these cases, the northern exposure's radiant component is less impactful and, in certain cases, may be omitted from a combi-sensor system's physical sensors. In one example of a building geographically located in a northern latitude, a combi-sensor system comprises three orthogonally-directed physical sensors facing approximately W, E, and S.
For buildings geographically located in the Southern hemisphere, the south facing facades are only exposed to morning and evening sun for a brief time (and only in summer months) which would be covered by an east and west facing physical sensor. In these cases, the southern exposure's radiant component is less impactful and, in certain cases, may be omitted from the combi-sensor system's physical sensors. In one example of a building geographically located in a southern latitude, a combi-sensor system comprises three orthogonally-directed physical sensors facing approximately W, E, and N.
In one embodiment, a combi-sensor system comprises three orthogonally-directed physical sensors installed at a building in southern California, which is in the Northern Hemisphere. The three orthogonally-directed physical sensors comprise an East-facing sensor at 90 degrees from North, a South-facing sensor at 180 degrees from North, and a West-facing sensor at 270 degrees from North.
Although the hardware elements, for example photosensors, may be installed at a building, algorithms and associated computing hardware may be located elsewhere, e.g. at a processing center or at the same building at the photosensors. Although typically the physical sensors are installed on the building façade, they may also be installed proximate the building and oriented as they would be if on the façade of the building, or both having some sensors on the building and some not on the building. Also, for example where two or more buildings are in the same vicinity and have similar orientations and configurations, the physical sensors may be on only one such building and the combi-sensor system serve the needs of control algorithms for window tinting functions of other buildings in the vicinity. In another example, where two or more buildings are in the same vicinity and have similar orientations and configurations, the physical sensors may be dispersed on different buildings while serving a single combi-sensor system and one or more building's window tinting control algorithms. Thus a group of sensors on a single building and/or a network of sensors in disparate locations can be part of a combi-sensor system that serves one or more buildings. Where weather and sun patterns are similar over larger geographical areas, a combi-sensor system may serve several buildings in that geographical area.
IV. Vertically Sparse Physical Sensors
Just as a combi-sensor system can be used to determine virtual sensor values by using physical sensor values about a azimuthal span horizontally, so can a combi-sensor system determine virtual sensor values at vertical levels (e.g., floors, or spaced apart horizontally and oriented the same direction) without physical sensors i.e. in a structure having vertically sparse physical sensors. In certain aspects, a combi-sensor system determines a combi-sensor value at intermediate levels between levels with physical sensors or at other levels without physical sensors. For example, certain lower floors of a building may be shaded by neighboring buildings, while upper floors are not. A combi-sensor system can be used to determine combi-sensor light values for virtual sensors on those lower floors that do not have physical sensors. In other aspects, a combi-sensor system can determine a combi-sensor value based on readings from multiple vertically separated physical sensors on a single facade. The values from the individual vertically separated physical sensors could be combined in the same way as the values from azimuthally separated sensors as described in Section V below. The combi-sensor value may be used as a combined output into Module C for all of the vertical sections on the facade, for example.
V. Techniques for Determining Combi-sensor Values for Virtual Sensors not in Phase with Physical Sensors
There are two main techniques for determining a combi-sensor value for a virtual facade-aligned sensor. The first technique combines readings from two or more physical sensors to determine an aggregate combi-sensor value that can be used for all orientations. The second technique interpolates readings from two or more physical sensors to the virtual facade-aligned sensor using a vector algorithm.
Technique 1.
The first technique combines readings at any given time from three or more physical sensors facing azimuthally distinct directions to determine a combi-sensor value. This combi-sensor value applies to all facade orientations for the given time. An aggregate envelope is an area enclosed by the curve defined by the aggregate combi-sensor values for that day. The aggregate value is determined by one of the following methods: 1) determining a maximum value of the physical sensor values, 2) averaging the physical sensor values, or 3) summing the physical sensor values.
Method 1—Maximum Value Method
The first method determines a combi-sensor value, at each sample time, which is the maximum value of all the readings taken by the three or more physical sensors. The determined maximum values generate an aggregate envelope that contains the solar radiation profiles from all possible facade orientations for the day. That is, all facades are experiencing a solar radiation at or lower than the maximum sensor value. This method retains the magnitude of output of a single physical sensor since each maximum value is of a single sensor at each sample time. Since the magnitude of the single physical sensor is retained, this allows for the combination of sensors in legacy installations or combination of combi-sensors and single sensors. That is, with this method, it does not matter how many sensors are added or removed from the combi-sensor system, the aggregate envelope should remain the same and thus, the magnitudes of these maximum values remain accurate.
Using the illustrated example shown in
Method 2—Average Value Method
The second method determines a combi-sensor value at a given time by averaging the readings taken by all the physical sensors at that time. This second method tends to soften the curve of the combi-sensor values and reduce the bounce. In this method, however, the magnitudes of the average combi-sensor values may be lower than a single physical sensor reading. Since the combi-sensor value may be much lower, tuning these combi-sensor values before inputting them into a control module may be desired. The difference in magnitude between an average combi-sensor value and a single physical sensor reading may be more pronounced as the number of physical sensors is increased, in certain circumstances. That is, the higher the number of physical sensors, the lower the average value in these cases. Tuning (scaling) to adjust the combi-sensor values can be used to get the aggregate values (output) back to realistic levels. That is, the combi-sensor values may be multiplied by a scaling factor such as 1.05, 1.1, 1.2, 1.3, 1.4, 1.5, etc. when using the average value method.
Method 3—Additive Method
In this third method, the combi-sensor value is determined by summing the readings at any given time from all the physical sensors. This method results in the highest magnitude combi-sensor value of the three methods. As with the average method, this third method may require tuning to return the relative magnitudes back to realistic output e.g. by using a scaling factor. That is, the combi-sensor values may be multiplied by a scaling factor such as 0.95, 0.9, 0.85, 0.8, 0.75, 0.7, 0.65, 0.6, 0.55, 0.50, etc. when using the average value method. In the additive method, the higher the number of physical sensors, the higher the aggregate value.
As discussed above,
The average value method of determining an aggregate curve has the lowest combi-sensor values of the three methods generally. In the morning, the average value method has combi-sensor values that are lower than the values of the theoretical solar radiation profile 201. In evening, the average value method has combi-sensor values that are higher than the values of the theoretical solar radiation profile 201. As shown, the additive (summing) method has the highest combi-sensor values of the three methods and has higher combi-sensor values than the values of the theoretical solar radiation profile 201 throughout day. The maximum value method has combi-sensor values closest to the theoretical solar radiation profile 201 in the morning and has combi-sensor values that are higher than the values of the theoretical solar radiation profile 201 in the evening.
In some embodiments, certain determinations in the control logic may be adjusted based on the type of combination method used to determine the combi-sensor value. For example, the threshold value used by Module C in the logic described in Section X may be adjusted based on the technique and method used to determine the combi-sensor value. In this example, the threshold value determines the actual irradiance level outside that determines whether it is a cloudy condition i.e. below this threshold value, it is determined that it is a cloudy day and Module C may decrease the tint level accordingly overriding Module A/B. In this example, the threshold value may be proportionally increased if being compared to a combi-sensor value determined with the additive sensor method or proportionally decreased if being compared to a combi-sensor value determined with the average sensor method. Combi-sensor systems can use one, two or all three of the combination methods to provide a combi-sensor value for a given façade for a given time of day to approximate as closely as possible the actual irradiance on that façade and therefore apply tinting algorithms, e.g. Intelligence™ modules, appropriately.
As mentioned above,
Although combi-sensor systems are not limited to the example of being used as input to a control system for electrochromic windows, according to this example the maximum value method generates combi-sensor values that perform with Module C closest to in-phase façade sensor readings when in cloudy conditions. The maximum value method improves sunny condition performance in this example as well. That is, the maximum value method performs better as input to Module C than an out-of phase sensor in sunny conditions. An in-phase sensor refers to a physical sensor that faces the same direction as the façade orientation. An out-of-phase sensor refers to a physical sensor that faces a direction that is not aligned to the direction of the façade. An out-of phase sensor is either trailing (i.e. in a direction with an azimuth angle less than the azimuth angle of the façade orientation) or leading (i.e. in a direction with an azimuth angle more than the azimuth angle of the façade orientation). The average value method generates combi-sensor values that perform with Module C better than an out-of-phase sensor. The additive method generates combi-sensor values that perform with Module C better than an out-of-phase sensor. All three methods perform with Module C that same as when using readings from an in-phase sensor.
Technique 2
The second technique uses a vector algorithm to interpolate solar radiation readings taken by two or more physical sensors to a virtual facade-aligned sensor directed at a different azimuth angle. That is, the virtual facade-aligned sensor is typically in a direction that is not aligned to any of the physical sensors at the structure. In one embodiment, the combi-sensor value of the virtual facade-aligned sensor is based on two or more of the physical sensors that are closest in azimuthal position to the virtual facade-aligned sensor. In one embodiment, the combi-sensor value of the virtual facade-aligned sensor is based on all the physical sensors.
VI. Misaligned Sensor Examples
In some cases, an installed physical sensor may not be properly aligned to its facade or may become misaligned i.e. not facing a normal direction to the corresponding facade. For example, it may have be improperly installed, may have become misaligned after installation, etc. In one embodiment, the combi-sensor system may determine the actual orientation of a misaligned physical sensor and adjust its readings for use at the corresponding facade orientation and/or for use in determining other combi-sensor values for other facades. To determine the actual orientation of a misaligned sensor, the combi-sensor system could determine the solar radiation profiles (irradiance vs. time) over two or more clear sky days for multiple orientations. The solar radiation profiles can be determined from a solar calculator or from an open-source program such as Radiance. These programs predict clear sky irradiance profiles for many different azimuthal positions. The combi-sensor system can compare the solar radiation profiles for multiple orientation s with the sensor output for two or more clear sky days. The combi-sensor system could determine the best matching solar radiation profile to determine the actual orientation to the sensor. Once the actual orientation of the sensor is determined, the readings from this incorrectly oriented sensor can be used to determine a combi-sensor value for a virtual facade-aligned sensor in the orientation of the corresponding facade with the misaligned sensor and for a virtual sensor in the orientation of other facades not having physical sensors.
In one embodiment, a virtual sensor is directed azimuthally with the wall/facade on which the misaligned sensor is mounted. The adjustment is accomplished by time shifting the misaligned sensor's output to correspond with the azimuthal position of the wall/facade. In other words, by using the actual position of the sun at a given time, one can apply a time shift factor to the misaligned sensor so that its output corresponds with the solar irradiance actually experienced on the façade. For example if the sensor is not orthogonal (facing directly outward as intended) from a façade, but rather at an angle which would allow the sensor to read solar irradiance levels that will be encountered by that façade in 10 minutes. Then a 10 minute time shift is applied to the sensor's output, for example, the façade's solar irradiance experienced is known 10 minutes prior to the façade actually being exposed to that level of irradiance. So, sensor inputs are read 10 minutes prior to the sun actually impinging directly (orthogonally) on the façade, since the sun is impinging directly on the sensor at that time.
VII. Combi-Sensor Methods
In general operation, the combi-sensor methods determine a combi-sensor value for each facade (or facet thereof) or for a representative facade of a zone of facades of a building. The combi-sensor value may be determined using either Technique 1 (any of the three methods) or by using Technique 2, as described in detail above. The combi-sensor value can be used as input to a one or more building control systems. For example, this combi-sensor method can be used to determine a combi-sensor value at each facade having an electrochromic window or other controllable component. The combi-sensor value can then be used by the control system to adjust the controllable component such as, for example, transitioning tint state (e.g., increasing tint, clearing, etc.) of an electrochromic window. This is the equivalent to having a “virtual” sensor on facades where no physical sensor is deployed.
In some embodiments, a combi-sensor value may be used as input to Module C described in Section X. In the case of a facade having an electrochromic window, the combi-sensor value can be used as input to Module C to determine whether to decrease tint in the electrochromic window based on whether the combi-sensor value is less than a certain value such as, for example, the theoretical clear sky irradiance. In some cases, a combi-sensor value for a representative window of a zone of electrochromic windows can be used to control the electrochromic windows in that zone of the building. Although control of electrochromic windows is described in many examples herein, other building systems may be controlled using combi-sensor values such as HVAC systems. For example, by knowing the solar irradiance on any given façade, the heat load can be managed by increasing or decreasing air conditioning on various interior sides of the building.
In embodiments that use Technique 2 to determine the combi-sensor value, the combi-sensor method may determine the two closest physical sensors to the facade. First, solar radiation readings from three or more physical sensors in the combi-sensor system are determined for clear sky day(s). In some cases, the physical sensors may take solar radiation readings for two or more clear sky days to generate “clear sky” solar radiation profiles associated with the directions of the physical sensors. A solar calculator or from an open-source program such as Radiance may be used to determine expected, theoretical solar radiation profiles for clear sky days. These programs can generate the theoretical “clear sky” profiles for different azimuthal positions. The actual daily solar radiation profiles (irradiance vs. time) from readings taken by the physical sensor(s) over two or more clear sky days can be compared to the expected theoretical output from the programs. The theoretical clear sky radiation profile from the program(s) that best agrees with the actual physical sensor solar radiation profile provides the actual azimuthal position of the physical sensor. The actual azimuthal position of the physical sensor(s) may be compared with the azimuthal position of the facade (e.g., provided in a lookup table) to determine any degree of misalignment of the facade with one of the physical sensors. This may be repeated for all the physical sensors in the combi-sensor system. This comparison can be also used to determine which two physical sensors are closest to the facade and azimuthally contain the facade. The closest physical sensor to the facade may be determined by comparing the actual azimuthal position of the physical sensors with the azimuthal position of the facade. The closest physical sensor has the smallest difference in azimuthal position from the facade.
VIII. Virtual Façade-aligned Sensor Values Used as Input to Building Control Systems
As discussed herein, combi-sensor values for facades may be used as input into building control systems such as thermal/comfort management systems. An example of such a building system that controls electrochromic windows is described in Section X. If used with logic described in Section X, the combi-sensor values may be input into Module C for a specific window/zone.
In certain embodiments, a control method that uses combi-sensor values does not prematurely override or erroneously override Module A/B on a sunny day for any window azimuth angle. A phase diagram of the yearly maximum impact of using a combi-sensor value based on the maximum approach method has a single point at the center showing that the combi-sensor value does not override Module A/B prematurely. In the associated system, the combi-sensor system has three physical sensors facing East, South and West.
The aggregate curves (dotted line) cover an envelope under the curves. In
According to the aggregate curves in
IX. Ring Sensor Example
In “ring sensor” embodiments, a combi-sensor system generally comprises a mast and a set of two or more physical sensors (e.g., 12 sensors) mounted to the mast. The physical sensors are facing outward to direct the sensors at distinctly different azimuth angles as discussed in sections above. The mast may be installed at/near the structure. For example, the mast of the ring sensor may be mounted on the top of a building in an unobstructed area. In many cases, the physical sensors may be equally-spaced in a ring arrangement (i.e. at the same radius from a central axis of the mast). For example, a ring sensor may be comprised of twelve (12) equally-spaced physical sensors directed at azimuth angles separated by 30 degrees and at/nearly the same radius from the central axis of the mast.
In ring sensor embodiments, the physical sensors may be mounted directly or indirectly to the mast. In certain aspects, a ring sensor comprises a circular tray mounted to one end of the mast. In these cases, the physical sensors may be located within this circular tray. A protective translucent casing may be provided over the physical sensors.
Each of the graphs in
Ring sensor embodiments may have one or more technical advantages. For example, an advantage of a ring sensor embodiment may be ease of installation. If using a ring sensor of more than 12 equally spaced sensors, the sensors do not need to be aligned to certain compass directions. In addition, the ring sensor may only require a single installation of a pre-constructed arrangement of physical sensors. This ring sensor embodiment may also avoid certain restrictions placed on sensors installations on the outer facades of the building since the ring sensor can be mounted to the top of the building.
X. Building Control Systems
In certain embodiments, a combi-sensor system provides a combi-sensor value for a facade of a structure as input to control building systems. For example, combi-sensor values can be used to control the transitioning to different tint states of one or more electrochromic window(s) in a building. Description of control methods for transitioning to different tint states can be found in PCT/US15/29675, titled “CONTROL METHOD FOR TINTABLE WINDOWS,” and filed on May 7, 2015, and U.S. patent application Ser. No. 13/772,969, titled “CONTROL METHOD FOR TINTABLE WINDOWS,” and filed on Feb. 21, 2014, both of which are hereby incorporated by reference in their entirety and for all purposes. An example of a management system for controlling electrochromic window(s) and other building systems is described below.
A. Overview of Electrochromic Devices
It should be understood that while disclosed embodiments described below focus on electrochromic windows (also referred to as smart windows), the concepts disclosed herein may apply to other types of tintable windows. For example, a tintable window incorporating a liquid crystal device or a suspended particle device, instead of an electrochromic device could be incorporated in any of the disclosed embodiments.
In order to orient the reader to the embodiments of systems, window controllers, and methods disclosed herein, a brief discussion of electrochromic devices is provided. This initial discussion of electrochromic devices is provided for context only, and the subsequently described embodiments of systems, window controllers, and methods are not limited to the specific features and fabrication processes of this initial discussion.
Electrochromic materials may be incorporated into, for example, windows for home, commercial and other uses. The color, transmittance, absorbance, and/or reflectance of such windows may be changed by inducing a change in the electrochromic material, that is, electrochromic windows are windows that can be darkened or lightened electronically. A small voltage applied to an electrochromic device of the window will cause them to darken; reversing the voltage causes them to lighten. This capability allows control of the amount of light that passes through the windows, and presents an opportunity for electrochromic windows to be used as energy-saving devices.
Electrochromic devices having distinct layers can be fabricated as all solid state devices and/or all inorganic devices. Such devices and methods of fabricating them are described in more detail in U.S. patent application Ser. No. 12/645,111, entitled “Fabrication of Low-Defectivity Electrochromic Devices,” filed on Dec. 22, 2009, and naming Mark Kozlowski et al. as inventors, and in U.S. patent application Ser. No. 12/645,159, entitled, “Electrochromic Devices,” filed on Dec. 22, 2009 and naming Zhongchun Wang et al. as inventors, both of which are hereby incorporated by reference in their entireties. It should be understood, however, that any one or more of the layers in the stack may contain some amount of organic material. The same can be said for liquids that may be present in one or more layers in small amounts. It should also be understood that solid state material may be deposited or otherwise formed by processes employing liquid components such as certain processes employing sol-gels or chemical vapor deposition.
Additionally, it should be understood that the reference to a transition between a bleached state and colored state is non-limiting and suggests only one example, among many, of an electrochromic transition that may be implemented. Unless otherwise specified herein (including the foregoing discussion), whenever reference is made to a bleached-colored transition, the corresponding device or process encompasses other optical state transitions such as non-reflective-reflective, transparent-opaque, etc. Further, the term “bleached” refers to an optically neutral state, for example, uncolored, transparent, or translucent. Still further, unless specified otherwise herein, the “color” of an electrochromic transition is not limited to any particular wavelength or range of wavelengths. As understood by those of skill in the art, the choice of appropriate electrochromic and counter electrode materials governs the relevant optical transition.
In embodiments described herein, the electrochromic device reversibly cycles between a bleached state and a colored state. In a similar way, the electrochromic device of embodiments described herein can be reversibly cycled between different tint levels (e.g., bleached state, darkest colored state, and intermediate levels between the bleached state and the darkest colored state). In certain aspects, an electrochromic device may include an electrochromic (EC) electrode layer and a counter electrode (CE) layer separated by an ionically conductive (IC) layer that is highly conductive to ions and highly resistive to electrons. As conventionally understood, the ionically conductive layer therefore prevents shorting between the electrochromic layer and the counter electrode layer. The ionically conductive layer allows the electrochromic and counter electrodes to hold a charge and thereby maintain their bleached or colored states. In electrochromic devices having distinct layers, the components form a stack which includes the ion conducting layer sandwiched between the electrochromic electrode layer and the counter electrode layer. The boundaries between these three stack components are defined by abrupt changes in composition and/or microstructure. Thus, the devices have three distinct layers with two abrupt interfaces.
In accordance with certain embodiments, the counter electrode and electrochromic electrodes are formed immediately adjacent one another, sometimes in direct contact, without separately depositing an ionically conducting layer. In some embodiments, electrochromic devices having an interfacial region rather than a distinct IC layer are employed. Such devices, and methods of fabricating them, are described in U.S. Pat. No. 8,300,298 and U.S. patent application Ser. No. 12/772,075 filed on Apr. 30, 2010, and U.S. patent application Ser. Nos. 12/814,277 and 12/814,279, filed on Jun. 11, 2010—each of the three patent applications and patent is entitled “Electrochromic Devices,” each names Zhongchun Wang et al. as inventors, and each is incorporated by reference herein in its entirety.
B. Window Controllers
A window controller is used to control the tint level of the electrochromic device of an electrochromic window. In some embodiments, the window controller is able to transition the electrochromic window between two tint states (levels), a bleached state and a colored state. In other embodiments, the controller can additionally transition the electrochromic window (e.g., having a single electrochromic device) to intermediate tint levels. In some disclosed embodiments, the window controller is able to transition the electrochromic window to four or more tint levels. Certain electrochromic windows allow intermediate tint levels by using two (or more) electrochromic lites in a single IGU, where each lite is a two-state lite.
In some embodiments, an electrochromic window can include an electrochromic device on one lite of an IGU and another electrochromic device on the other lite of the IGU. If the window controller is able to transition each electrochromic device between two states, a bleached state and a colored state, the electrochromic window is able to attain four different states (tint levels), a colored state with both electrochromic devices being colored, a first intermediate state with one electrochromic device being colored, a second intermediate state with the other electrochromic device being colored, and a bleached state with both electrochromic devices being bleached. Embodiments of multi-pane electrochromic windows are further described in U.S. Pat. No. 8,270,059, naming Robin Friedman et al. as inventors, titled “MULTI-PANE ELECTROCHROMIC WINDOWS,” which is hereby incorporated by reference in its entirety.
In some embodiments, the window controller is able to transition an electrochromic window having an electrochromic device capable of transitioning between two or more tint levels. For example, a window controller may be able to transition the electrochromic window to a bleached state, one or more intermediate levels, and a colored state. In some other embodiments, the window controller is able to transition an electrochromic window incorporating an electrochromic device between any number of tint levels between the bleached state and the colored state. Embodiments of methods and controllers for transitioning an electrochromic window to an intermediate tint level or levels are further described in U.S. Pat. No. 8,254,013, naming Disha Mehtani et al. as inventors, titled “CONTROLLING TRANSITIONS IN OPTICALLY SWITCHABLE DEVICES,” which is hereby incorporated by reference in its entirety.
In some embodiments, a window controller can power one or more electrochromic devices in an electrochromic window. Typically, this function of the window controller is augmented with one or more other functions described in more detail below. Window controllers described herein are not limited to those that have the function of powering an electrochromic device to which it is associated for the purposes of control. That is, the power source for the electrochromic window may be separate from the window controller, where the controller has its own power source and directs application of power from the window power source to the window. However, it is convenient to include a power source with the window controller and to configure the controller to power the window directly, because it obviates the need for separate wiring for powering the electrochromic window.
Further, the window controllers described in this section are described as standalone controllers which may be configured to control the functions of a single window or a plurality of electrochromic windows, without integration of the window controller into a building control network or a building management system (BMS). Window controllers, however, may be integrated into a building control network or a BMS, as described further in the Building Management System section of this disclosure.
In
In disclosed embodiments, a building may have at least one room having an electrochromic window between the exterior and interior of a building. One or more sensors may be located to the exterior of the building and/or inside the room. In embodiments, the output from the one or more sensors may be input to the signal conditioning module 465 of the window controller 450. In some cases, the output from the one or more sensors may be input to a BMS, as described further in the Building Management Systems section. Although the sensors of depicted embodiments are shown as located on the outside vertical wall of the building, this is for the sake of simplicity, and the sensors may be in other locations, such as inside the room or on other surfaces to the exterior, as well. In some cases, two or more sensors may be used to measure the same input, which can provide redundancy in case one sensor fails or has an otherwise erroneous reading.
Exterior sensor 510 is a device, such as a photosensor, that is able to detect radiant light incident upon the device flowing from a light source such as the sun or from light reflected to the sensor from a surface, particles in the atmosphere, clouds, etc. The exterior sensor 510 may generate a signal in the form of electrical current that results from the photoelectric effect and the signal may be a function of the light incident on the sensor 510. In some cases, the device may detect radiant light in terms of irradiance in units of watts/m2 or other similar units. In other cases, the device may detect light in the visible range of wavelengths in units of foot candles or similar units. In many cases, there is a linear relationship between these values of irradiance and visible light.
Irradiance values from sunlight can be predicted based on the time of day and time of year as the angle at which sunlight strikes the earth changes. Exterior sensor 510 can detect radiant light in real-time, which accounts for reflected and obstructed light due to buildings, changes in weather (e.g., clouds), etc. For example, on cloudy days, sunlight would be blocked by the clouds and the radiant light detected by an exterior sensor 510 would be lower than on cloudless days.
In some embodiments, there may be one or more exterior sensors 510 associated with a single electrochromic window 505. Output from the one or more exterior sensors 510 could be compared to one another to determine, for example, if one of exterior sensors 510 is shaded by an object, such as by a bird that landed on exterior sensor 510. In some cases, it may be desirable to use relatively few sensors in a building because some sensors can be unreliable and/or expensive. In certain implementations, a single sensor or a few sensors may be employed to determine the current level of radiant light from the sun impinging on the building or perhaps one side of the building. A cloud may pass in front of the sun or a construction vehicle may park in front of the setting sun. These will result in deviations from the amount of radiant light from the sun calculated to normally impinge on the building.
Exterior sensor 510 may be a type of photosensor. For example, exterior sensor 510 may be a charge coupled device (CCD), photodiode, photoresistor, or photovoltaic cell. One of ordinary skill in the art would appreciate that future developments in photosensor and other sensor technology would also work, as they measure light intensity and provide an electrical output representative of the light level.
In some embodiments, output from exterior sensor 510 may be input to the signal conditioning module 465. The input may be in the form of a voltage signal to signal conditioning module 465. Signal conditioning module 465 passes an output signal to the window controller 450. Window controller 450 determines a tint level of the electrochromic window 505, based on various information from the configuration file 475, output from the signal conditioning module 465, override values. Window controller 450 and then instructs the PWM 460, to apply a voltage and/or current to electrochromic window 505 to transition to the desired tint level.
In disclosed embodiments, window controller 450 can instruct the PWM 460, to apply a voltage and/or current to electrochromic window 505 to transition it to any one of four or more different tint levels. In disclosed embodiments, electrochromic window 505 can be transitioned to at least eight different tint levels described as: 0 (lightest), 5, 10, 15, 20, 25, 30, and 35 (darkest). The tint levels may linearly correspond to visual transmittance values and solar gain heat coefficient (SGHC) values of light transmitted through the electrochromic window 505. For example, using the above eight tint levels, the lightest tint level of 0 may correspond to an SGHC value of 0.80, the tint level of 5 may correspond to an SGHC value of 0.70, the tint level of 10 may correspond to an SGHC value of 0.60, the tint level of 15 may correspond to an SGHC value of 0.50, the tint level of 20 may correspond to an SGHC value of 0.40, the tint level of 25 may correspond to an SGHC value of 0.30, the tint level of 30 may correspond to an SGHC value of 0.20, and the tint level of 35 (darkest) may correspond to an SGHC value of 0.10.
Window controller 450 or a master controller in communication with the window controller 450 may employ any one or more predictive control logic components to determine a desired tint level based on signals from the exterior sensor 510 and/or other input. The window controller 450 can instruct the PWM 460 to apply a voltage and/or current to electrochromic window 505 to transition it to the desired tint level.
C. An Example of Predictive Control Logic
In disclosed embodiments, predictive control logic is used to implement methods of determining and controlling a desired tint level for the electrochromic window 505 or other tintable window that accounts for occupant comfort and/or energy conservation considerations. This predictive control logic may employ one or more logic modules.
Module A can be used to determine a tint level that considers occupant comfort from direct sunlight through the electrochromic window 505 onto an occupant or their activity area. The tint level is determined based on a calculated penetration depth of direct sunlight into the room and the space type (e.g., desk near window, lobby, etc.) in the room at a particular instant in time. In some cases, the tint level may also be based on providing sufficient natural lighting into the room. In many cases, the penetration depth is the value calculated at a time in the future to account for glass transition time. The concern addressed in Module A is that direct sunlight may penetrate so deep into the room 500 as to show directly on an occupant working at a desk or other work surface in a room. Publicly available programs can provide calculation of the sun's position and allow for easy calculation of penetration depth.
The predictive control logic may implement one or more of the logic Modules A, B and C separately for each electrochromic window 505 in the building. Each electrochromic window 505 can have a unique set of dimensions, orientation (e.g., vertical, horizontal, tilted at an angle), position, associated space type, etc. A configuration file with this information and other information can be maintained for each electrochromic window 505. The configuration file 475 may be stored in the computer readable medium 470 of the local window controller 450 of the electrochromic window 505 or in the BMS described later in this disclosure. The configuration file 475 can include information such as a window configuration, an occupancy lookup table, information about an associated datum glass, and/or other data used by the predictive control logic. The window configuration may include information such as the dimensions of the electrochromic window 505, the orientation of the electrochromic window 505, the position of the electrochromic window 505, etc.
A lookup table describes tint levels that provide occupant comfort for certain space types and penetration depths. That is, the tint levels in the occupancy lookup table are designed to provide comfort to occupant(s) that may be in the room 500 from direct sunlight on the occupant(s) or their workspace. An example of an occupancy lookup table is shown in
The space type is a measure to determine how much tinting will be required to address occupant comfort concerns for a given penetration depth and/or provide comfortable natural lighting in the room. The space type parameter may take into consideration many factors. Among these factors is the type of work or other activity being conducted in a particular room and the location of the activity. Close work associated with detailed study requiring great attention might be at one space type, while a lounge or a conference room might have a different space type. Additionally, the position of the desk or other work surface in the room with respect to the window is a consideration in defining the space type. For example, the space type may be associated with an office of a single occupant having a desk or other workspace located near the electrochromic window 505. As another example, the space type may be a lobby.
In certain embodiments, one or more modules of the predictive control logic can determine desired tint levels while accounting for energy conservation in addition to occupant comfort. These modules may determine energy savings associated with a particular tint level by comparing the performance of the electrochromic window 505 at that tint level to a datum glass or other standard reference window. The purpose of using this reference window can be to ensure that the predictive control logic conforms to requirements of the municipal building code or other requirements for reference windows used in the locale of the building. Often municipalities define reference windows using conventional low emissivity glass to control the amount of air conditioning load in the building. As an example of how the reference window 505 fits into the predictive control logic, the logic may be designed so that the irradiance coming through a given electrochromic window 505 is never greater than the maximum irradiance coming through a reference window as specified by the respective municipality. In disclosed embodiments, predictive control logic may use the solar heat gain coefficient (SHGC) value of the electrochromic window 505 at a particular tint level and the SHGC of the reference window to determine the energy savings of using the tint level. Generally, the value of the SHGC is the fraction of incident light of all wavelengths transmitted through the window. Although a datum glass is described in many embodiments, other standard reference windows can be used. Generally the SHGC of the reference window (e.g., datum glass) is a variable that can be different for different geographical locations and window orientations, and is based on code requirements specified by the respective municipality.
Generally, buildings are designed to have an HVAC with the capacity to fulfill the maximum expected heating and/or air-conditioning loads required at any given instance. The calculation of required capacity may take into consideration the datum glass or reference window required in a building at the particular location where the building is being constructed. Therefore, it is important that the predictive control logic meet or exceed the functional requirements of the datum glass in order to allow building designers to confidently determine how much HVAC capacity to put into a particular building. Since the predictive control logic can be used to tint the window to provide additional energy savings over the datum glass, the predictive control logic could be useful in allowing building designers to have a lower HVAC capacity than would have been required using the datum glass specified by the codes and standards.
Particular embodiments described herein assume that energy conservation is achieved by reducing air conditioning load in a building. Therefore, many of the implementations attempt to achieve the maximum tinting possible, while accounting for occupant comfort level and perhaps lighting load in a room having with the window under consideration. However, in some climates, such as those at far northern and for southern latitudes, heating may be more of a concern than air conditioning. Therefore, the predictive control logic can be modified, specifically, road reversed in some matters, so that less tinting occurs in order to ensure that the heating load of the building is reduced.
In certain implementations, the predictive control logic has only two independent variables that can be controlled by an occupant (end user), building designer, or building operator. These are the space types for a given window and the datum glass associated with the given window. Often the datum glass is specified when the predictive control logic is implemented for a given building. The space type can vary, but is typically static. In certain implementations, the space type may be part of the configuration file maintained by the building or stored in the local window controller 450. In some cases, the configuration file may be updated to account for various changes in the building. For example, if there is a change in the space type (e.g., desk moved in an office, addition of desk, lobby changed into office area, wall moved, etc.) in the building, an updated configuration file with a modified occupancy lookup table may be stored in the computer readable medium 470. As another example, if an occupant is hitting manual override repeatedly, then the configuration file may be updated to reflect the manual override.
At step 620, logic Modules A, B, and C perform calculations to determine a tint level for each electrochromic window 505 at a single instant in time ti. These calculations can be performed by the window controller 450. In certain embodiments, the predictive control logic predictively calculates how the window should transition in advance of the actual transition. In these cases, the calculations in Modules A, B, and C can be based on a future time around or after transition is complete. In these cases, the future time used in the calculations may be a time in the future that is sufficient to allow the transition to be completed after receiving the tint instructions. In these cases, the controller can send tint instructions in the present time in advance of the actual transition. By the completion of the transition, the window will have transitioned to a tint level that is desired for that time.
At step 630, the predictive control logic allows for certain types of overrides that disengage the algorithm at Modules A, B, and C and define override tint levels at step 640 based on some other consideration. One type of override is a manual override. This is an override implemented by an end user who is occupying a room and determines that a particular tint level (override value) is desirable. There may be situations where the user's manual override is itself overridden. An example of an override is a high demand (or peak load) override, which is associated with a requirement of a utility that energy consumption in the building be reduced. For example, on particularly hot days in large metropolitan areas, it may be necessary to reduce energy consumption throughout the municipality in order to not overly tax the municipality's energy generation and delivery systems. In such cases, the building may override the tint level from the predictive control logic described herein to ensure that all windows have a particularly high level of tinting. Another example of an override may be if there is no occupant in the room, for example during a weekend in a commercial office building. In these cases, the building may disengage one or more Modules that relate to occupant comfort and all the windows may have a high level of tinting in cold weather and low level of tinting in warm weather.
At step 650, the tint levels are transmitted over a network to electrochromic device(s) in one or more electrochromic windows 505 in the building. In certain embodiments, the transmission of tint levels to all windows of a building may be implemented with efficiency in mind. For example, if the recalculation of tint level suggests that no change in tint from the current tint level is required, then there is no transmission of instructions with an updated tint level. As another example, the building may be divided into zones based on window size. The predictive control logic may recalculate tint levels for zones with smaller windows more frequently than for zones with larger windows.
In some embodiments, the logic in
Also, there may be certain adaptive components of the predictive control logic of embodiments. For example, the predictive control logic may determine how an end user (e.g. occupant) tries to override the algorithm at particular times of day and makes use of this information in a more predictive manner to determine desired tint levels. In one case, the end user may be using a wall switch to override the tint level provided by the predictive logic at a certain time each day to an override value. The predictive control logic may receive information about these instances and change the predictive control logic to change the tint level to the override value at that time of day.
At step 700, window controller 450 uses Module A to determine a tint level for occupant comfort to prevent direct glare from sunlight penetrating the room 500. Window controller 450 uses Module A to calculate the penetration depth of direct sunlight into the room 500 based on the sun's position in the sky and the window configuration from the configuration file. The position of the sun is calculated based on the latitude and longitude of the building and the time of day and date. The occupancy lookup table and space type are input from a configuration file for the particular window. Module A outputs the Tint level from A to Module B.
The goal of Module A is to ensure that direct sunlight or glare does not strike the occupant or his or her workspace. The tint level from Module A is determined to accomplish this purpose. Subsequent calculations of tint level in Modules B and C can reduce energy consumption and may require even greater tint. However, if subsequent calculations of tint level based on energy consumption suggest less tinting than required to avoid interfering with the occupant, the predictive logic prevents the calculated greater level of transmissivity from being executed to assure occupant comfort.
At step 800, the tint level calculated in Module A is input into Module B. A tint level is calculated based on predictions of irradiance under clear sky conditions (clear sky irradiance). Window controller 450 uses Module B to predict clear sky irradiance for the electrochromic window 505 based on window orientation from the configuration file and based on latitude and longitude of the building. These predictions are also based on a time of day and date. Publicly available software such as the RADIANCE program, which is an open-source program, can provide the calculations for predicting clear sky irradiance. The SHGC of the datum glass is also input into Module B from the configuration file. Window controller 450 uses Module B to determine a tint level that is darker than the tint level in A and transmits less heat than the datum glass is predicted to transmit under maximum clear sky irradiance. Maximum clear sky irradiance is the highest level of irradiance for all times predicted for clear sky conditions.
At step 900, a tint level from B and predicted clear sky irradiance are input to Module C. Real-time irradiance values are input to Module C based on measurements from an exterior sensor 510. Window controller 450 uses Module C to calculate irradiance transmitted into the room if the window were tinted to the Tint level from Module B under clear sky conditions. Window controller 450 uses Module C to find the appropriate tint level where the actual irradiance through the window with this tint level is less than or equal to the irradiance through the window with the Tint level from Module B. The tint level determined in Module C is the final tint level.
Much of the information input to the predictive control logic is determined from fixed information about the latitude and longitude, time and date. This information describes where the sun is with respect to the building, and more particularly with respect to the window for which the predictive control logic is being implemented. The position of the sun with respect to the window provides information such as the penetration depth of direct sunlight into the room assisted with the window. It also provides an indication of the maximum irradiance or solar radiant energy flux coming through the window. This calculated level of irradiance can be modified by sensor input which might indicate that there is a reduction from the maximum amount of irradiance. Again, such reduction might be caused by a cloud or other obstruction between the window and the sun.
At step 720, window controller 450 uses Module A to calculate the penetration depth of direct sunlight into the room 500 at the particular instant in time used in step 710. Module A calculates the penetration depth based on the calculated position of the sun and window configuration information including the position of the window, dimensions of the window, orientation of the window (i.e. direction facing), and the details of any exterior shading. The window configuration information is input from the configuration file associated with the electrochromic window 505. For example, Module A can be used to calculate the penetration depth of the vertical window shown in
At step 730, a tint level is determined that will provide occupant comfort for the penetration depth calculated in step 720. The occupancy lookup table is used to find a desired tint level for the space type associated with the window, for the calculated penetration depth, and for the acceptance angle of the window. The space type and occupancy lookup table are provided as input from the configuration file for the particular window.
An example of an occupancy lookup table is provided in
At step 830, the window controller 450 uses Module B to determine the maximum amount of irradiance that would be transmitted through a datum glass into the room 500 at that time (i.e. determines Maximum Datum Inside Irradiance). The calculated Maximum Clear Sky Irradiance from step 820 and the datum glass SHGC value from the configuration file can be used to calculate the Maximum Irradiance inside the space using the equation: Maximum Datum Inside Irradiance=Datum Glass SHGC×Maximum Clear Sky Irradiance.
At step 840, window controller 450 uses Module B to determine inside irradiance into the room 500 having a window with the current tint level based on the equation. The calculated Clear Sky Irradiance from step 810 and the SHGC value associated with the current tint level can be used to calculate the value of the inside irradiance using the equation: Tint level Irradiance=Tint level SHGC×Clear Sky Irradiance.
In one embodiment, one or more the steps 705, 810 and 820 may be performed by a solar position calculator separate from Modules A and B. A solar position calculator refers to logic that determines the position of the sun at a particular future time and makes predictive determinations (e.g., predicts clear sky irradiance) based on the sun's position at that future time. The solar position calculator may perform one or more steps of the methods disclosed herein. The solar position calculator may be a portion of the predictive control logic performed by one or more of the components of the master window controller. For example, the solar position calculator may be part of the predictive control logic shown in
At step 850, window controller 450 uses Module B to determine whether the inside irradiance based on the current tint level is less than or equal to the maximum datum inside irradiance and the tint level is darker than the tint level from A. If the determination is NO, the current tint level is incrementally increased (darkened) at step 860 and the inside irradiance is recalculated at step 840. If the determination is YES at step 850, Module B ends.
At step 910, window controller 450 uses Module C to calculate irradiance transmitted into the room through an electrochromic window 505 tinted to the Tint level from B under clear sky conditions. This Calculated Inside Irradiance can be determined using the equation: Calculated Inside Irradiance=SHGC of Tint Level from B×Predicted Clear Sky Irradiance from B.
At step 920, window controller 450 uses Module C to find the appropriate tint level where the actual irradiance (=SR×Tint level SHGC) through the window with this tint level is less than or equal to the irradiance through the window with the Tint level from B (i.e. Actual Inside Irradiance≤Calculated Inside Irradiance). In some cases, the module logic starts with the tint level from B and incrementally increases the tint level until the Actual Inside Irradiance≤Calculated Inside Irradiance. The tint level determined in Module C is the final tint level. This final tint level may be transmitted in tint instructions over the network to the electrochromic device(s) in the electrochromic window 505.
A program such as the open source program Radiance, is used to determine clear sky irradiance based on window orientation and latitude and longitude coordinates of the building for both a single instant in time ti and a maximum value for all times. The datum glass SHGC and calculated maximum clear sky irradiance are input into Module B. Module B increases the tint level calculated in Module A in steps and picks a tint level where the Inside radiation is less than or equal to the Datum Inside Irradiance where: Inside Irradiance=Tint level SHGC×Clear Sky Irradiance and Datum Inside Irradiance=Datum SHGC×Maximum Clear Sky Irradiance. However, when Module A calculates the maximum tint of the glass, module B doesn't change the tint to make it lighter. The tint level calculated in B is then input into Module C. The predicted clear sky irradiance is also input into Module C.
Module C calculates the inside irradiance in the room with an electrochromic window 505 having the tint level from B using the equation: Calculated Inside Irradiance=SHGC of Tint Level from B×Predicted Clear Sky Irradiance from B. Module C then finds the appropriate tint level that meets the condition where actual inside irradiance is less than or equal to the Calculated Inside Irradiance. The actual inside irradiance is determined using the equation: Actual Inside Irradiance=SR×Tint level SHGC. The tint level determined by Module C is the final tint level in tint instructions sent to the electrochromic window 505.
In some embodiments, tintable windows for the exterior windows of the building (i.e., windows separating the interior of the building from the exterior of the building), may be grouped into zones, with tintable windows in a zone being instructed in a similar manner. For example, groups of electrochromic windows on different floors of the building or different sides of the building may be in different zones. For example, on the first floor of the building, all of the east facing electrochromic windows may be in zone 1, all of the south facing electrochromic windows may be in zone 2, all of the west facing electrochromic windows may be in zone 3, and all of the north facing electrochromic windows may be in zone 4. As another example, all of the electrochromic windows on the first floor of the building may be in zone 1, all of the electrochromic windows on the second floor may be in zone 2, and all of the electrochromic windows on the third floor may be in zone 3. As yet another example, all of the east facing electrochromic windows may be in zone 1, all of the south facing electrochromic windows may be in zone 2, all of the west facing electrochromic windows may be in zone 3, and all of the north facing electrochromic windows may be in zone 4. As yet another example, east facing electrochromic windows on one floor could be divided into different zones. Any number of tintable windows on the same side and/or different sides and/or different floors of the building may be assigned to a zone.
In some embodiments, electrochromic windows in a zone may be controlled by the same window controller. In some other embodiments, electrochromic windows in a zone may be controlled by different window controllers, but the window controllers may all receive the same output signals from sensors and use the same function or lookup table to determine the level of tint for the windows in a zone.
In some embodiments, electrochromic windows in a zone may be controlled by a window controller or controllers that receive an output signal from a transmissivity sensor. In some embodiments, the transmissivity sensor may be mounted proximate the windows in a zone. For example, the transmissivity sensor may be mounted in or on a frame containing an IGU (e.g., mounted in or on a mullion, the horizontal sash of a frame) included in the zone. In some other embodiments, electrochromic windows in a zone that includes the windows on a single side of the building may be controlled by a window controller or controllers that receive an output signal from a transmissivity sensor.
In some embodiments, a sensor (e.g., photosensor) may provide an output signal to a window controller to control the electrochromic windows 505 of a first zone (e.g., a master control zone). The window controller may also control the electrochromic windows 505 in a second zone (e.g., a slave control zone) in the same manner as the first zone. In some other embodiments, another window controller may control the electrochromic windows 505 in the second zone in the same manner as the first zone.
In some embodiments, a building manager, occupants of rooms in the second zone, or other person may manually instruct (using a tint or clear command or a command from a user console of a BMS, for example) the electrochromic windows in the second zone (i.e., the slave control zone) to enter a tint level such as a colored state (level) or a clear state. In some embodiments, when the tint level of the windows in the second zone is overridden with such a manual command, the electrochromic windows in the first zone (i.e., the master control zone) remain under control of the window controller receiving output from the transmissivity sensor. The second zone may remain in a manual command mode for a period of time and then revert back to be under control of the window controller receiving output from the transmissivity sensor. For example, the second zone may stay in a manual mode for one hour after receiving an override command, and then may revert back to be under control of the window controller receiving output from the transmissivity sensor.
In some embodiments, a building manager, occupants of rooms in the first zone, or other person may manually instruct (using a tint command or a command from a user console of a BMS, for example) the windows in the first zone (i.e., the master control zone) to enter a tint level such as a colored state or a clear state. In some embodiments, when the tint level of the windows in the first zone is overridden with such a manual command, the electrochromic windows in the second zone (i.e., the slave control zone) remain under control of the window controller receiving outputs from the exterior sensor. The first zone may remain in a manual command mode for a period of time and then revert back to be under control of window controller receiving output from the transmissivity sensor. For example, the first zone may stay in a manual mode for one hour after receiving an override command, and then may revert back to be under control of the window controller receiving output from the transmissivity sensor. In some other embodiments, the electrochromic windows in the second zone may remain in the tint level that they are in when the manual override for the first zone is received. The first zone may remain in a manual command mode for a period of time and then both the first zone and the second zone may revert back to be under control of the window controller receiving output from the transmissivity sensor.
Any of the methods described herein of control of a tintable window, regardless of whether the window controller is a standalone window controller or is interfaced with a building network, may be used control the tint of a tintable window.
Wireless or Wired Communication
In some embodiments, window controllers described herein include components for wired or wireless communication between the window controller, sensors, and separate communication nodes. Wireless or wired communications may be accomplished with a communication interface that interfaces directly with the window controller. Such interface could be native to the microprocessor or provided via additional circuitry enabling these functions.
A separate communication node for wireless communications can be, for example, another wireless window controller, an end, intermediate, or master window controller, a remote control device, or a BMS. Wireless communication is used in the window controller for at least one of the following operations: programming and/or operating the electrochromic window 505, collecting data from the EC window 505 from the various sensors and protocols described herein, and using the electrochromic window 505 as a relay point for wireless communication. Data collected from electrochromic windows 505 also may include count data such as number of times an EC device has been activated, efficiency of the EC device over time, and the like. These wireless communication features is described in more detail below.
In one embodiment, wireless communication is used to operate the associated electrochromic windows 505, for example, via an infrared (IR), and/or radio frequency (RF) signal. In certain embodiments, the controller will include a wireless protocol chip, such as Bluetooth, EnOcean, WiFi, Zigbee, and the like. Window controllers may also have wireless communication via a network. Input to the window controller can be manually input by an end user at a wall switch, either directly or via wireless communication, or the input can be from a BMS of a building of which the electrochromic window is a component.
In one embodiment, when the window controller is part of a distributed network of controllers, wireless communication is used to transfer data to and from each of a plurality of electrochromic windows via the distributed network of controllers, each having wireless communication components.
In some embodiments, more than one mode of wireless communication is used in the window controller distributed network. For example, a master window controller may communicate wirelessly to intermediate controllers via WiFi or Zigbee, while the intermediate controllers communicate with end controllers via Bluetooth, Zigbee, EnOcean, or other protocol. In another example, window controllers have redundant wireless communication systems for flexibility in end user choices for wireless communication.
Wireless communication between, for example, master and/or intermediate window controllers and end window controllers offers the advantage of obviating the installation of hard communication lines. This is also true for wireless communication between window controllers and BMS. In one aspect, wireless communication in these roles is useful for data transfer to and from electrochromic windows for operating the window and providing data to, for example, a BMS for optimizing the environment and energy savings in a building. Window location data as well as feedback from sensors are synergized for such optimization. For example, granular level (window-by-window) microclimate information is fed to a BMS in order to optimize the building's various environments.
D. Another Example of Predictive Control Logic
In
Network controller 1408 receives sensor readings from one or more sensors (e.g., an outside light sensor) and may also convert the sensor reading into W/m2. The network controller 1408 is in electronic communication with the window controller 1410 via either CANbus or CANOpen protocol. The network controller 1408 communicates the converted sensor readings to the window controller 1410.
In
Master scheduler 1502 runs the control programs in the schedule according to time in terms of the date and time of day based on a 24-hour day. Master scheduler 1502 may determine the date in terms of a calendar date and/or the day of the week based on a 7-day week with five weekdays (Monday through Friday) and two weekend days (Saturday and Sunday). Master scheduler 1502 may also determine whether certain days are holidays. Master scheduler 1502 may automatically adjust the time of day for daylight savings time based on the location of the tintable windows, which is determined by site data 1506.
In one embodiment, master scheduler 1502 may use a separate holiday schedule. The user may have determined which control program(s) to use during the holiday schedule. The user may determine which days will be included in the holiday schedule. Master scheduler 1502 may copy the basic schedule set up by the user and allow the user to set up their modifications for the holidays in the holiday schedule.
When preparing the schedule employed by master scheduler 1502, the user may select the zone or zones (Zone Selection) of the building where the selected program(s) will be employed. Each zone includes one or more tintable windows. In some cases, a zone may be an area associated with a space type (e.g., offices having a desk at a particular position, conference rooms, etc.) or may be associated with multiple space types. For example, the user may select Zone 1 having offices to: 1) Monday through Friday: heat up at 8 am in morning to 70 degrees and turn on air conditioning to at 3 pm in afternoon to keep temperature in offices to 80 degrees, and then turn off all air conditioning, and heat at 5 pm during weekdays, and 2) (Saturday and Sunday) turn off heat and air conditioning. As another example, the user may set Zone 2 having a conference room to run the predictive control logic of
When preparing the schedule with programs that may use sensor input, the user may also be able to select the sensor or sensors used in the programs. For example, the user may select a sensor located on the roof or a sensor located near or at the tintable window. As another example, the user may select an ID value of a particular sensor.
The portion of the predictive control logic employed by window controller 1410 also includes a user interface 1504 in electronic communication with master scheduler 1502. User interface 1504 is also in communication with site data 1506, zone/group data 1508, and sense logic 1516. The user may input their schedule information to prepare the schedule (generate a new schedule or modify an existing schedule) using user interface 1504. User interface 1504 may include an input device such as, for example, a keypad, touchpad, keyboard, etc. User interface 1504 may also include a display to output information about the schedule and provide selectable options for setting up the schedule. User interface 1504 is in electronic communication with a processor (e.g., microprocessor), which is in electronic communication with a computer readable medium (CRM). Both the processor and CRM are components of the window controller 1410. The logic in master scheduler 1502 and other components of the predictive control logic may be stored on the computer readable medium of window controller 1410.
The user may enter their site data 1506 and zone/group data 1508 using user interface 1504. Site data 1506 includes the latitude, longitude, and GMT Offset for the location of the building. Zone/group data includes the position, dimension (e.g., window width, window height, sill width, etc.), orientation (e.g., window tilt), external shading (e.g., overhang depth, overhang location above window, left/right fin to side dimension, left/right fin depth, etc.), datum glass SHGC, and occupancy lookup table for the one or more tintable windows in each zone of the building. In
When preparing (or modifying) the schedule, the user selects the control program that master scheduler 1502 will run at different time periods in each of the zones of a building. In some cases, the user may be able to select from multiple control programs. In one such case, the user may prepare a schedule by selecting a control program from a list of all control programs (e.g., menu) displayed on user interface 1405. In other cases, the user may have limited options available to them from a list of all control programs. For example, the user may have only paid for the use of two control programs. In this example, the user would only be able to select one of the two control programs paid for by the user.
Returning to
The Zone/Group Data includes information about the representative window of each zone. In one case, the representative window may be one of the windows in the zone. In another case, the representative window may be a window having average properties (e.g., average dimensions) based on averaging all the properties from all the windows in that zone.
The predictive control logic employed by window controller 1410 also includes a solar position calculator 1512. Solar position calculator 1512 includes logic that determines the position of the sun, sun azimuth and sun altitude, at an instance in time. In
The control logic employed by window controller 1410 also includes schedule logic 1518, which is in communication with the sense logic 1516, the user interface 1405, the solar position calculator 1512, and Module 1 1406. The schedule logic 1518 includes logic that determines whether to use the tint level passing through the intelligence logic 1520 from Module 1 1406 or use another tint level based on other considerations. For example, as sunrise and sunset times change throughout the year, the user may not want to reprogram the schedule to account for these changes. The schedule logic 1518 may use the sunrise and sunset times from the solar position calculator 1512 to set an appropriate tint level before sunrise and after sunset without requiring the user to reprogram the schedule for these changing times. For example, the schedule logic 1518 may determine that according to the sunrise time received from the solar position calculator 1512 the sun has not risen and that a pre-sunrise tint level should be used instead of the tint level passed from Module 1 1406. The tint level determined by the schedule logic 1518 is passed to sense logic 1516.
Sense logic 1516 is in communication with override logic 1514, schedule logic 1518, and user interface 1405. Sense logic 1516 includes logic that determines whether to use the tint level passed from schedule logic 1518 or use another tint level based on the sensor data received through the BACnet interface 1408 from one or more sensors. Using the example in the paragraph above, if schedule logic 1518 determines that it the sun has not risen and passed a pre-sunrise tint level and the sensor data shows that the sun has actually risen, then sense logic 1516 would use the tint level passed from Module 1 1406 through schedule logic 1518. The tint level determined by sense logic 1516 is passed to override logic 1514.
BMS 1407 and network controller 1408 are also in electronic communication with a demand response (e.g., utility company) to receive signals communicating the need for a high demand (or peak load) override. In response to receiving these signals from the demand response, BMS 1407 and/or network controller 1408 may send instructions through BACnet Interface 1408 to override logic 1514 that will process the override information from the demand response. Override logic 1514 is in communication with BMS 1407 and network controller 1408 through the BACnet Interface 1408, and also in communication with sense logic 1516.
Override logic 1514 allows for certain types of overrides to disengage predictive control logic and use an override tint level based on another consideration. Some examples of types of overrides that may disengage predictive control logic include a high demand (or peak load) override, manual override, vacant room override, etc. A high demand (or peak load) override defines a tint level from the demand response. For a manual override, an end user may enter the override value at a wall switch either manually or through a remote device. A vacant room override defines an override value based on a vacant room (i.e. no occupant in the room). In this case, the sense logic 1516 may receive sensor data from a sensor (e.g., motion sensor) indicating that the room is vacant and sense logic 1516 may determine an override value and relay the override value to override logic 1514. The override logic 1514 can receive an override value and determine whether to use the override value or use another value, such as another override value received from a source having higher priority (i.e., demand response). In some cases, the override logic 1514 may operate by steps similar to the override steps 630, 640, and 650 described with respect to
The control logic employed by window controller 1410 also includes intelligence logic 1520 that can shut off one or more of Modules A 1550, B 1556 and C 1560. In one case, the intelligence logic 1520 may be used to shut off one or more Modules where the user has not paid for those Modules. Intelligence logic 1520 may prevent the use of certain more sophisticated features such as the penetration calculation made in Module A. In such cases, a basic logic is used that “short-circuits” the solar calculator information and uses it to calculate tint levels, possibly with the assistance of one or more sensors. This tint level from the basic logic is communicated to schedule logic 1518.
Intelligence logic 1520 can shut off one or more of the Modules (Module A 1550, Module B 1556 and Module C 1560) by diverting certain communications between the window controller 1410 and Module 1 1406. For example, the communication between the solar position calculator 1512 and Module A 1550 goes through intelligence logic 1520 and can be diverted to schedule logic 1518 by intelligence logic 1520 to shut off Module A 1550, Module B 1556 and Module C 1560. As another example, the communication of tint level from Module A at 1552 to the Clear Sky Irradiance calculations at 1554 goes through intelligence logic 1520 and can be diverted instead to schedule logic 1518 to shut off Module B 1556 and Module C 1560. In yet another example, the communication of tint level from Module B at 1556 to Module C 1560 goes through intelligence logic 1520 and can be diverted to schedule logic 1518 to shut off Module C 1560.
Module 1 1406 includes logic that determines and returns a tint level to the schedule logic 1518 of window controller 1410. The logic predicts a tint level that would be appropriate for the future time provided by the time of day portion 1510. The tint level is determined for a representative tintable window associated with each of the zones in the schedule.
In
In
Module A 1550 then determines the tint level that will provide occupant comfort for the calculated penetration depth. Module A 1550 uses the occupancy lookup table retrieved from the zone/group data 1508 to determine the desired tint level for the space type associated with the representative tintable window, for the calculated penetration depth, and for the acceptance angle of the window. Module A 1550 outputs a tint level at step 1552.
The maximum clear sky irradiance incident the representative tintable window is predicted for all times in the logic 1554. The clear sky irradiance at the future time is also predicted based on the latitude and longitude coordinates of the building and the representative window orientation (i.e. direction the window is facing) from the site data 1506 and the zone/group data 1508. These clear sky irradiance calculations can be performed by the sun position calculator 1512 in other embodiments.
Module B 1556 then calculates new tint levels by incrementally increasing the tint level. At each of these incremental steps, the Inside Irradiance in the room based on the new tint level is determined using the equation: Inside Irradiance=Tint level SHGC×Clear Sky Irradiance. Module B selects the tint level where Inside Irradiance is less than or equal to Datum Inside Irradiance (Datum SHGC×Max. Clear sky Irradiance) and the tint level is not lighter than Tint Level from A. Module B 1556 outputs the selected tint level from B. From the Tint level from B, logic 1558 calculates the outside irradiance and the calculated skylight irradiance.
Module C 1560 makes a determination of whether a sensor reading of irradiance is less than the clear sky irradiance. If the determination result is YES, then the tint level being calculated is made incrementally lighter (clearer) until the value matches or is less than a tint level calculated as Sensor Reading×Tint Level SHGC, but not to exceed datum inside Irradiance from B. If the determination result is NO, then the tint level being calculated is made darker in incremental steps as done in Module B 1556. Module C outputs the tint level. Logic 1562 determines that the tint level from Module C is the final tint level and returns this final tint level (Tint level from Module C) to the schedule logic 1518 of the window controller 1410.
In one aspect, Module 1 1406 may also include a fourth Module D that can predict the effects of the surrounding environment on the intensity and direction of sunlight through the tintable windows in the zone. For example, a neighboring building or other structure may shade the building and block some light from passing through the windows. As another example, reflective surfaces (e.g., surfaces having snow, water, etc.) from a neighboring building or other surfaces in the environment surrounding the building may reflect light into the tintable windows. This reflected light can increase the intensity of light into the tintable windows and cause glare in the occupant space. Depending on the values of the intensity and direction of sunlight predicted by Module D, Module D may modify the tint level determined from Modules A, B, and C or may modify certain determinations from Modules A, B, and C such as, for example, the penetration depth calculation or the acceptance angle of the representative window in the Zone/Group data.
In some cases, a site study may be conducted to determine the environment surrounding the building and/or one or more sensors may be used to determine the effects of the surrounding environment. Information from the site study may be static information based on predicting the reflectance and shading (surrounding) effects for a time period (e.g., a year), or may be dynamic information that can be updated on a periodic basis or other timed basis. In one case, Module D may use the site study to modify the standard acceptance angle and associated θ1 and θ2 of the representative window of each zone retrieved from the Zone/group data. Module D may communicate this modified information regarding the representative windows other modules of the predictive control logic. The one or more sensors employed by Module D to determine the effects of the surrounding environment may be the same sensors used by other modules (e.g., by Module C) or may be different sensors. These sensors may be specifically designed to determine the effects of the surrounding environment for Module D.
To operate the predictive control logic shown in
E. Filter(s) for Making Tinting Decisions Based on Rapidly Changing Conditions
In some systems, once a decision is made to tint a tintable window to a particular end state, the window is committed to complete that transition until reaching the end state. Such systems cannot adjust the final tint state during transition, and can only wait until transition is complete. If an unsuitable end tint state is selected by these systems, the window is committed to this unsuitable tint level during the transition cycle and additionally any time that it takes to transition the window to a more appropriate tint level. Since tint/clear times take 5 to 30 minutes, for example, an unsuitable selection could tie up a window in an inappropriate tint level for a substantial period of time which could make conditions uncomfortable for the occupant.
Rapidly changing conditions (e.g., weather change such as intermittent clouds on a sunny day, a fog bank moving in or out, fog burning off to sunshine, etc.) combined with long transition times can cause control methods to “bounce” between end tint states. In addition, such control methods can decide on an end tint state based on a condition that changes immediately after the method commits to the transition, in which case the window is locked into an unsuitable tint level until the transition is complete. For example, consider a mostly sunny day with dappled clouds. A control method may react to a drop in illumination values when a cloud passes by and when the values rebound, glare conditions could exist. Even though the cloud passes by quickly, the window is committed to transitioning to the inappropriately low end tint state for at least the duration of the transition cycle. During this time, solar radiation enters the room which could also make it uncomfortably warm for the occupant.
An example of a rapidly changing weather condition is a foggy morning that breaks into sunshine. Certain systems would determine a low tint level at the beginning of the day based on the low illumination readings during the morning fog. This low tint level would be inappropriately low during the period when the weather quickly transitions to clear sky after the fog burns off. In this example, a more appropriate higher tint level for the clear sky may not be determined for a substantial period of time (e.g., 35-45 minutes). Another example of a rapidly changing condition is the onset of a reflection from an object such as, for example, a parked car or an adjacent building's window.
Certain embodiments described herein include window control methods that use multiple filters to make tinting decisions that address rapidly changing conditions. In certain cases, these filters can be used to determine a more appropriate end tint state during a current transition cycle to adjust the tint level of the window to a level appropriate for current conditions. One type of filter is a box car filter (sometimes called a sliding window filter), which employs multiple sensor readings of illumination values running in time. A box car value is a calculated central tendency (e.g., mean, average, or median) of a number, n, of contiguous sensor samples (readings of illumination values over time). Typically, the sensor samples are measurements of external radiation (e.g., by a sensor located on the outside of a building). A single sensor can be used to take sensor samples for multiple windows such as windows in a particular zone of a building. The sensor readings generally take readings on a periodic basis at a uniform frequency (sampling rate). For example, the sensor may take samples at a rate in the range of about one sample every 30 seconds to one sample every twenty minutes. In one embodiment, a sensor takes samples at a rate of one sample every minute. In some cases, one or more timers may also be used to maintain the tint at a current setting determined using a box car value.
In certain aspects, control methods use a short box car and one or more long box cars (filters) to make tinting decisions. A short box car (e.g., one that employs sample values taken over 10 minutes, 20 minutes, 5 minutes, etc.) is based on a smaller number of sensor samples (e.g., n=1, 2, 3, . . . 10, etc.) relative to the larger number of sensor samples (e.g., n=10, 20, 30, 40, etc.) in a long box car (e.g., one that employs sample values taken over 1 hour, 2 hours, etc.). In one case, a short box car value is a median value of sensor samples and a long box car value is an average value of sensor samples. Since a short box car value is based on a smaller number of sensor samples, short box car values more closely follow the sensor readings than long box car values. Thus, short box car values respond to rapidly changing conditions more quickly and to a greater degree than the long box car values. Although both the calculated short and long box car values lag behind the sensor readings, the short box car will lag behind to a lesser extent than the long box car.
Short box cars react more quickly than long box cars to current conditions. A long box car filter smoothes the window controller response to frequent short duration weather fluctuations, while a short box car does not smooth so well but responds better to rapid and significant weather changes. In the case of a passing cloud, a control algorithm using the long box car illumination value will not react quickly to the current passing cloud condition. In this case, the long box car illumination value should be used in tinting decisions to determine an appropriate high tint level. In the case of fog burning off, it may be more appropriate to use the short term box car illumination value in tinting decisions. In this case, the short term box car reacts more quickly to the new sunny condition after the fog burns off. By using the short term box car value to make tinting decisions, the tintable window quickly adjusts to the sunny condition and keeps the occupant comfortable as the fog rapidly burns off.
In certain aspects, control methods evaluate the difference between the short and long term box car values to determine which illumination value to use in tinting decisions. When the difference (short term value minus long term value) is positive and exceeds a first (positive) threshold (e.g., 20 W/m2), the value of the short term boxcar is used to calculate a tint value. Note that a positive value corresponds to a transition to brightening (a greater radiant intensity outside the window). In some implementations, a first timer is set when the positive threshold is exceeded, in which case a currently calculated tint value is maintained for a prescribed amount of time of the first timer. Using the first timer will favor glare control by holding the window in a more tinted state and preventing too many transitions that may annoy an occupant. On the other hand, when the difference between the short car and long car values is less than the threshold (or negative), the long term box value is used to calculate the next tint state. And if the difference is negative and greater than a second (negative) threshold, then a second timer may be set. The positive threshold values may be in the range of about 1 Watts/m2 to 200 Watts/m2 and the negative threshold values may be in the range of about −200 Watts/m2 to −1 Watts/m2. The calculated tint value based on the long box car is maintained during a prescribed amount of the time of the second timer. Once the control method determines which box car value to use, the method will make tinting decisions based on whether the box car value is above an upper limit, below a lower limit, or between the upper and lower limits. If above the upper limit, Modules A and B (or just B in some cases) are used to determine tint change. If above the lower limit and below the upper limit, Modules A, B, and C (or just B and C in some cases) are used to determine tint change. If below the lower limit, a defined tint level is applied (e.g., nominally clear). In certain cases, the lower limit may be in the range of 5 Watts/m2 to 200 Watts/m2 and the upper limit may be in the range of 50 Watts/m2 to 400 Watts/m2.
More specifically with reference back to
In some control methods, the long box car value is updated with sensor readings and is never reset during the day. If sensor readings were to change significantly during the day (e.g., when a storm front arrived), these long box car values would lag substantially behind the rapid change in sensor readings and would not reflect the rapid change. For example, the long box car values are significantly higher than the sensor readings after a substantial drop in external illumination. If these high long box car values are used to calculate a tint level, the windows may be over-tinted until the long box cars had time to load with more current sensor readings. In certain aspects, control methods reset the long box car after a rapid change in illumination so that the long box car can be loaded with more current sensor readings.
More specifically with reference back to
At the end of the second timer period, if we were to simply use the logic without resetting the long box car, the second timer would again be implemented and the long box car values would be used during the time period (as before). As you can see, this would be the wrong result, as the actual sensor readings (and the short box car) data show it is a dull day and the window doesn't need to be tinted according to the long box car data (it's still way off from reality). In this scenario, a long term box car is reset at the timer start period. In other words, once the timer is triggered, this simultaneously triggers resetting the long box car to start loading with sensor data. Under this logic, at the end of the second timer, the short term box car's value is compared with the reset long box car and the delta now would more closely reflect actual sensor readings.
With reference back to
Modifications, additions, or omissions may be made to any of the above-described predictive control logic, other control logic and their associated control methods (e.g., logic described with respect to
Also, modifications, additions, or omissions may be made to the above-described systems or components of a system without departing from the scope of the disclosure. The components of the may be integrated or separated according to particular needs. For example, the master network controller 1403 and intermediate network controller 1408 may be integrated into a single window controller. Moreover, the operations of the systems can be performed by more, fewer, or other components. Additionally, operations of the systems may be performed using any suitable logic comprising software, hardware, other logic, or any suitable combination of the preceding.
It should be understood that the present invention as described above can be implemented in the form of control logic using computer software in a modular or integrated manner. Based on the disclosure and teachings provided herein, a person of ordinary skill in the art will know and appreciate other ways and/or methods to implement the present invention using hardware and a combination of hardware and software.
Any of the software components or functions described in this application, may be implemented as software code to be executed by a processor using any suitable computer language such as, for example, Java, C++ or Perl using, for example, conventional or object-oriented techniques. The software code may be stored as a series of instructions, or commands on a computer readable medium, such as a random access memory (RAM), a read only memory (ROM), a magnetic medium such as a hard-drive or a floppy disk, or an optical medium such as a CD-ROM. Any such computer readable medium may reside on or within a single computational apparatus, and may be present on or within different computational apparatuses within a system or network.
Although the foregoing disclosed embodiments have been described in some detail to facilitate understanding, the described embodiments are to be considered illustrative and not limiting. It will be apparent to one of ordinary skill in the art that certain changes and modifications can be practiced within the scope of the appended claims.
One or more features from any embodiment may be combined with one or more features of any other embodiment without departing from the scope of the disclosure. Further, modifications, additions, or omissions may be made to any embodiment without departing from the scope of the disclosure. The components of any embodiment may be integrated or separated according to particular needs without departing from the scope of the disclosure.
Claims
1. A combination sensor comprising:
- a set of two or more physical sensors facing different directions proximate a structure, and configured to measure solar radiation in different directions; and
- a virtual sensor configured to determine a combi-sensor value at a facade of the structure based at least in part on solar radiation readings from the set of physical sensors, the facade lacking a physical sensor operable to measure solar radiation in a direction of the facade.
2. The combination sensor of claim 1, wherein the combi-sensor value is determined by combining the solar radiation readings from the set of physical sensors, wherein the combi-sensor value applies to the facade at any orientation.
3. The combination sensor of claim 2, wherein the combi-sensor value is a maximum value of the solar radiation readings of the set of physical sensors.
4. The combination sensor of claim 2, wherein the combi-sensor value is an average value of the solar radiation readings of the set of physical sensors.
5. The combination sensor of claim 2, wherein the combi-sensor value is a sum of the solar radiation readings of the set of physical sensors.
6. The combination sensor of claim 1, wherein the combi-sensor value is an interpolated value from the solar radiation readings of two physical sensors of the set of physical sensors that are closest to the facade.
7. The combination sensor of claim 1, wherein the combi-sensor value of the virtual sensor is determined by shifting in time a solar radiation value of one of the set of physical sensors.
8. The combination sensor of claim 1, wherein the set of physical sensors comprises four orthogonally directed or approximately orthogonally directed sensors.
9. The combination sensor of claim 8, wherein the four orthogonally directed or approximately orthogonally directed sensors are directed to face North, East, South, and West.
10. The combination sensor of claim 1, wherein the set of physical sensors comprises three physical sensors.
11. The combination sensor of claim 1, wherein the three physical sensors are directed to face approximately West, East, and South.
12. The combination sensor of claim 1,
- further comprising a mast mounted to the structure,
- wherein the set of physical sensors is mounted to the mast in a ring sensor arrangement, wherein the mast is configured to elevate the set of physical sensors in a ring sensor arrangement away from the structure.
13. The combination sensor of claim 12, wherein the set of physical sensors comprises twelve physical sensors.
14. The combination sensor of claim 13, wherein the twelve physical sensors are equally spaced.
15. The combination sensor of claim 14, wherein the set of physical sensors comprises twelve physical sensors that are equally spaced about the central axis of the mast.
16. A method comprising:
- determining solar radiation readings taken by a set of two or more physical sensors facing different directions proximate a structure; and
- determining a combi-sensor value of a virtual sensor at a facade of the structure based at least in part on the solar radiation readings taken by the set of physical sensors, the facade lacking a physical sensor operable to measure solar radiation in direction of the facade.
17. The method of claim 16, wherein determining the combi-sensor value comprises combining the solar radiation readings of the set of physical sensors, wherein the combi-sensor value applies to the facade at any orientation.
18. The method of claim 17, wherein combining the solar radiation readings comprises determining a maximum value of the solar radiation readings of the set of physical sensors.
19. The method of claim 17, wherein combining the solar radiation readings comprises averaging the solar radiation readings of the set of physical sensors.
20. The method of claim 17, wherein combining the solar radiation readings comprises summing the solar radiation readings of the set of physical sensors.
21. The method of claim 16, wherein determining the combi-sensor value comprises interpolating from the solar radiation readings of two physical sensors of the set of physical sensors that are closest to the facade.
22. The method of claim 21, further comprising:
- determining solar radiation readings taken by the set of physical sensors for one or more clear sky days;
- determining a degree of misalignment between (i) a facade of the virtual sensor and (ii) each of the set of physical sensors; and
- determining the two physical sensors of the set of physical sensors that are closest to the facade based at least in part on the degree of misalignment determined for each of the set of physical sensors.
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Type: Grant
Filed: Sep 29, 2015
Date of Patent: Jan 21, 2020
Patent Publication Number: 20170276542
Assignee: VIEW, Inc. (Milpitas, CA)
Inventors: Erich R. Klawuhn (Los Altos, CA), Douglas S. Silkwood (Santa Clara, CA), Jason Zedlitz (Rocklin, CA), Stephen Clark Brown (San Mateo, CA), Dhairya Shrivastava (Los Altos, CA)
Primary Examiner: Jamil Ahmed
Application Number: 15/514,480
International Classification: G01J 1/02 (20060101); E06B 9/24 (20060101); G01J 1/42 (20060101); E06B 9/68 (20060101);